AU668350B2

AU668350B2 - Building element and method of manufacturing such element

Info

Publication number: AU668350B2
Application number: AU17581/92A
Authority: AU
Inventors: Hussain Munir
Original assignee: ECOMAX ACOUSTICS Ltd
Current assignee: ECOMAX ACOUSTICS Ltd
Priority date: 1992-04-08
Filing date: 1992-04-08
Publication date: 1996-05-02
Anticipated expiration: 2012-04-08
Also published as: FI944621A0; ES2108113T3; NO180649B; NO943747L; EP0635086B1; FI103212B; JPH07506158A; ATE157726T1; NO943747D0; WO1993021402A1; FI103212B1; DE69222063D1; NO180649C; EP0635086A1; AU1758192A; FI944621A; US5502931A

Abstract

PCT No. PCT/SE92/00229 Sec. 371 Date Oct. 7, 1994 Sec. 102(e) Date Oct. 7, 1994 PCT Filed Apr. 8, 1992 PCT Pub. No. WO93/21402 PCT Pub. Date Oct. 28, 1993.An integral structural element having improved sound and/or vibration dampening capacity and being composed of two support plates (1, 2) having therebetween spaced layers (3) of a viscoelastic material formed by a liquid synthetic elastomeric material having good adhesive properties and having a temperature resistance high enough to stand the temperature rise occuring due to the internal friction of the material while subjected to vibrations. The viscoelastic material between said two support plates (1, 2) is formed as strings of elastomeric material which are spaced from each other by a distance of 50-500 mm leaving space between the two support plates (1, 2) in the areas between adjacent strings of viscoelastic material (3). Each string (3) of dampening material has a material thickness of 1-5 mm, and a width of 10-50 mm. The structural element may, at the surface thereof to be mounted on a structural base, carry a mat of a natural or synthetic felt fibre material, having a product weight of 300-1200 g/m2 and having a thickness of 3-10 mm.

Description

SGPf DATE 18/11/93 AOJP DATE 27/01/94 PCT NUMBER PCT/SE92002291 1 AU9217581 IIAlrt A-lfl a.

.PCT)

(51) International Patent Classification 5 (11) International Publication Number: WO 93/21402 E04B 1/82 Al 4B 1/82 (43) International Publication Date: 28 October 1993 (28.10.93) (21) International Application Number: PCT/SE92/00229 Published With international search report.

(22) International Filing Date: 8 April 1992 (08.04.92) (71) Applicant (for all designated States except US): ECOMAX 4 COUSTICS LTD. [SE/SE]; P 54S 4 (72) Inventor; and Inventor/Applicant (for US onl) MUNIR, Hussain [GB/ 6 8 3 GB]; Gomm road, High Wycombe HPI3 7DJ (GB).

(74) Agent: AVELLAN-HULTMAN PATENTBYRA AB; Olle Avellan Hultman, Box 5366, S-102 46 Stockholm (SE).

(81) Designated States: AU, CA, FI, JP, NO, US, European patent (AT, BE, CH, DE, DK, ES, FR, GB, GR, IT, LU, MC, NL, SE).

(54)Title: BUILDING ELEMENT AND METHOD OF MANUFACTURING SUCH ELEMENT s 1 a.

(57) Abstract An integral structural element having improved sound and/or vibration dampening capacity and being composed of two iupport plates 2) having therebetween spaced layers of a viscoelastic material formed by a liquid synthetic elastomeric material having good adhesive properties and having a temperature resistance high enough to stand the temperature rise occuring due to the internal friction of the material while subjected to vibrations. The viscoelastic material between said two support plates 2) is formed as strings of elastomeric material which are spaced from each other by a distance of 50-500 mm leaving an air space between the two support plates 2) in the areas between adjacent strings of viscoelastic material Each string of dampening material has a material thickness of 1-5 mm, and a width of 10-50 mm. The structural element may, at the surface thereof to be mounted on a structural base, carry a mat of a natural or synthetic felt fibre material, having a product weight of 300-1200 g/m 2 and having a thickness of 3-10 mm.

WO 93/21402 PCT/SE92/00229 BUILDING ELEMENT AND METHOD OF MANUFACTURING SUCH ELEMENT The present invention generally relates to a building element, and the invention is more particularly concerned with a structural or a non-structural building element having improved sound damping and vibration damping properties and being of the known type formed as an integral building unit and composed by two superimposed plate like structural parts having therebetween spaced thin strings or strips of-a-viscoelastic material.

By damping properties is meant, in the following, both sound damping properties and vibration damping properties, and the invention is intended to damp both low frequency, medium frequency and high frequency sound and vibration. In house building by means of modern building material like concrete, gypsum boards, light weight concrete blocks, different types of plastic materials, but also by means of timber, building board, chip board and other types of wooden material there are often problems in that sounds, vibrations etc. transmit from one apartment to another, both vertically and horizontally, not only by vibrations etc. in the material itself but also by air borne sounds and vibrations. Therefore the invention is concerned with a structural or non-structural building element for use as a sound and vibration damping building element in house building, like in floors, walls, ceilings etc.

Sound and vibration transportation also causes the same type of problems in many types of apparatus like in telephone boxes, in loud speakers, in motor cars, in air planes, in ships, in motor hoods, in refrigerators etc.

Thus, by building material is meant any type of material which can be used as floor structures, wall structures, ceiling structures etc. in ordinary house building, and also for the manufacture of any other types of objects where there is a wish to take advantage of the sound damping or the vibration damping properties of the building element according to the invention or of both the sound damping and the vibration damping properties thereof.

A dampening structural element of the above mentioned type is known for instance from the British patent No 1,514,516 which element comprises two superimposed support elements like two metal plates, concret slabs, plaster sheets or wooden fibre sheets having between said elements discontinuously extenC. -g strips or grids of a viscoelastic material presenting air spaces between said strips or grids.

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WO 93/21402 2 PCT/SE92/00229 In the manufacture of said known type of structural element there is used a sheet of viscoelastic material which is on both sides covered with glue or an adhesive material, for instance a double sticking tape. For obtaining the intermediate strips of viscoelastic material of the product said composite viscoelastic sheet is cut into strips which are thereafter placed spaced from each other on a first support element, whereafter the second support element is laid down over said first support element having mounted thereon said spaced strips of viscoelastic material.

The cutting of the viscoelastic composite sheet material is complicated, both in that the cutting knife or roller knife easily sticks to the glue material; generally it is necessary to freeze the viscoelastic material in order to make it practically possible to cut it into strips; the known viscoelastic materials often are too hard to give a particularly good damping effect; the method is labour consuming and time consuming; there is often a risk that the composite structural element held together by the three-layer viscoelastic material, including both the damping strip itself and also the two glue or tape layers, is delaminated, which is in particular a problem in using the structural element in walls and ceilings.

The object of the invention therefore has been to suggest a structural composite element of the above mentioned type having improved sound damping and vibration damping properties as compared with previously known damping elements of the art; which element can be manufactured quickly and without involving much labour; which is more safely combined to a unitary product than the known elements; which can be safely applied even to porous support elements to form a safe joint between such elements; which is not apt to delamination; which has basically only one layer of material for providing both the connection between the two supporting element parts and for providing the particularly good damping effect; which can be manufactured in continuous lengths, and can be cut into desired plate sizes; which can be formed with cooperating groove and tenon means for The inventioned is based on the observation SUBSTITUTE SHEET I ISA/SE b WO 93/21402 PCT/SE92/00229 that surprisingly good damping effects can be obtained by using certain synthetic elastomeric compounds, that the best damping effects are obtained if the viscoelastic material is provided in the form of strings, dots etc. which are spaced from each other, and if the viscoelastic material parts have a predetermined thickness and predetermined width, that certain viscoelastic materials have a long lasting damping capability and are very resistant to aging, that such elastomeric (viscoelastic) materials can successfully be used in an originally liquid form in the continuous process of manufacture of the structural building element, whereby a liquid viscoelastic glue or synthetic rubber material is applied in liquid form to one of the support elements in the form of spaced strings having a predetermined width and thickness, and onto which is thereafter the second support element press applied.

The liquid viscoelastic glue can be applied by portioning nozzles, by rollers or by any other known method whereby the first support element is preferably moved past the glue application means.

As examples of useful viscoelastic liquid material may be mentioned styrene rubber, nitrilic rubber, and still more preferably silicon rubber, chloroprenic rubber and acrylic rubber, all having good adhesive properties and all preferably having a temperature resistance or maximum service temperature of 100 0 C or more to be able to stand the temperature rise occuring due to the internal friction of the viscoelastic material while subjected to sound and vibration.

In a prrefeed embodimet of the inventive method a first layer of the viscoelastic material, that is a glue or rubber material, is applied in liquid form to a first support element in the form of strings or dots etc. of a predetermined width and thickness to provide the intended viscoelastic layer; the glue is allowed to set or polymerize throughout, which will generally take about 4-8 hours at normal room temperatures; in a second step a thin layer of the same glue material is applied on top of the polymerized elastomeric layer as a connection means for the superimposed second support element; immediately thereafter said second support element is press applied on top of the thin connection layer; after the second glue layer has set or polymerized the structural element can be cut, SUBSTITUTE SHEET NT ISA/SE 4 trimmed, be formed with groove and tenon means etc.

Alternatively the liquid synthetic damping material is mould into strips having the desired thickness and width and are thereafter covered with a thin layer of an adequate glue on one side, preferably the same type of material as that of the polymeric strip; before the glue has set the strip is applied to a first support element; is supplied with a thin layer of glue on the upper surface thereof; and the second support element is press applied to the first support element and the viscoelastic material.

It has proved that a thickness of between 1 and or preferably 1.5 to 2.5mm of the damping viscoelastic layer gives a surprisingly good effect. A less good damping effect is obtained with damping strips, dots etc.

having less thickness than 1.0-1.5mm. It has been found that a fully covering damping layer gives a less good damping effect than several spaced strings of damping material. Depending on the type of load from which vibrations are to be dampened there may be used damping 20 strings of said thickness having a width of about ten times 4*4t11 the thickness, ie. a width of about 10-50mm.

The dampening strings preferably are spaced from it St each other by a distance which is about 5-10 times the t 4 twidth of the string, ie. that the damping strings are I €t 25 spaced 50-500mm. For a light weight load a spacing within the higher range of spacing is preferred, for a heavy load K a spacing within the lower range of spacing is preferred.

As a final step in the manufacture of the building element according the invention a felt material is glued to the bottom surface of the structural element, consisting of the two support elements of board, timber, metal, concrete, plastic material etc. and having the viscoelastic strings therebetween, that is the surface facing the mounting surface like the floor, the wall, the ceiling etc. Said felt material may be a natural or synthetic felt fibre material having a thickness which is i i 3-10mm or preferably 5-10mm and also preferably having a

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j~P~S~TZ product weight of 300-1200 g/m 2 Very good damping effects have been acknowledged for ordinary house floor structural elements by using, at the bottom surface of the lower support element a 100% polyester felt of needle/thermally bonded fibres, having a product weight of 300-1200g/m 2 and having a thickness of 3-10mm, or preferably 5-9mm. Other useful types of synthetic felt mats are made of viscose, polypropylene, polyurethane and polyamid (Nylon). Bonded glass fib- erial may be incorporated as a reinforcing element in a felt mat. Also natural fibre mats of wool or cotton are useful but it should in some applications be foreseen that such mats are not subjected to moisture.

The invention is now to be described in connection to the accompanying drawing in which figure 1 is a fragmentary vertical cross section view of a first stage in the manufacture of a structural element according to the t invention. Figure 2 is a cross section view of a ready structural element according to the invention. Figure 3 shows, partially in a broken up view two structural 20 elements connected to each other. Figure 4 is a tt z perspective view illustrating a method of applying the viscoelastic material to a first support plate in the structural element of the invention. Figures 5-9 are five successive cross sectional views illustrating a preferred tt I Q 25 method of the manufacture of a structural element of the type shown in figure 2. Figure 10 is a diagrammatical cross section through an available floor/ceiling of a building in which the invention has been tested, referred to as Test 1, and figures 11, 12 and 13 are alterative embodiments of a damping element according to the invention mounted in the same building and referred as Test 2, 3 and 4 respectively. Figure 14 is a diagram showing the damping of airborne sound passing the floor of figures 11- 13, and figure 15, finally, is a similar diagram showing the impact transmission through the same floor.

The structural element of figure 1 comprises two support plates 1 and 2 which are spaced from each other by A4/i LU

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1 L1; 5A means of spaced strings 3 of a viscoelastic material of the above mentioned type which may be a synthetic rubber material having a thickness of 1-5mm, a width of 10-50mm, and which strings may be spaced from each other by 500mm. The support plates 1 and 2 can be of any known material like timber, fibre board, building board, chip board, plywood, metal plate, concrete, plastic plate or any combination of said materials. The thickness of the support plates 1 and 2 can be varied as desired and for the actual use. For an ordinary house floor structure the plates 1 and 2 may each have a width of 3-22mm, or for many purposes preferably 8-15mm. The lower plate 1, which is adapted to face the floor of the house can be made thinner than the upper plate 2, for instance so that the lower plate 1 has a thickness of 3-8mm and the upper plate has a Sthickness of 8-22mm or-vice versa.

Figure 2 shows a complete structural element, which differs from the base element shown in figure 1 in that it has a bottom felt mat 4 as defined above, for i, 20 instance a polyester mat having a thickness of about 3which is glue connected to the bottom surface of the bottom 4 t41 44 41N 4 WO 93/21402 PCF/SE92/0229 support plate 1.

Figure 3 shows two structural elements 5 and 6 adapted to be laid on a concrete base, on a light weight concrete base or on a timber base. The elements 5 and 6 are formed with groove and tenon means 7 and 8 at two edges or along all edges thereof for making it possible to join several elements to form for instance an integral floor, wall or ceiling of a housing.

In the method of the invention there is used a liquid viscoelastic material of the above mentDned type. As illustrated in figure 4 said fluid glue/dampening material is preferably applied by means of several parallel nozzles 9 each leaving a string 10 of dampening material on a bottom structural plate 11 moving at a controlled speed past the nozzles 9. Each nozzle 9 leaves a string of material which is of a predetermined width and thickness. The nozzles 9 ire spaced with the same distance as the desired spacing of the strings 10. The spacing of the nozzles 9, like the speed of the bottom plate 11 and the thickness and width of the dampening strings can be varied as desired considering the field of use for the dampening structural element. It is to be understood that the application of the dampening strings 10 can be made by hand or by means of rollers etc.

Figure 5-9 diagrammatically illustrate a method of manufacturing a structural element according to the invention: Figure 5 illustrates how the bottom plate 11 is moved in the direction of the arrow past the nozzle 9 which deposits a string 10 of dampening material on top of the plate 11; Figure 6 illustrates that the dampening material 10 is allowed to completely set or polymerize which will take 4-6 hours at normal room temperature; the material may be kept in this condition for several days or weeks until the process is to be proceeded; Figure 7 illustrates that a thin layer 12 of a glue, preferably of the same material as in the dampening string 10 is laid out or sprayed onto said string 10 from a nozzle 13; Figure 8 shows that immediately thereafter the second support element 14, the upper element, is laid down on the strings 10, 12 of dampening material and is pressed thereon by a predetermined pressure thereby completing the process for the manufacture of the structural element of figure 1; In case of making the structural element of figure 2 a felt 16 is sprayed with glue 17 and the element completed in figure 8 is laid down on SUBSTITUTE SHEET ISA/SE 0 WO 93/21402 7 PCT/SE92/00229 said felt 16 and is pressed thereto by a pressure 18, and the glue 17 is allowed to set or polymerize.

Alternatively to the method illustrated in figures 5-9 it is also possible to mould the strings 10 separately by using the nozzles 9, whereby the strings can be moulded in or on an adhesive repellent material. After said moulded strings have polymerized completely they can be stored or can be used directly in thle process, whereby a thin layer of glue is applied to one surface of the strings, or to the upper surface of the bottom plate 11, the strings are press connected to the plate 11, glue is aplied to the upper surface of the strings 10 and the process proceeds like in figures 7-9 Figure 10 shows the sound transmission through an ordinary timber floor of an apartment house. As shown in the diagram the structural element of the invention is best suited for dampening of high frequency sound or vibrations but is also to some extent useful for low frequency sound or vibrations. The un-dampened sound transmission in the actual building is shown with the full line, the sound dampened by the structure of figure 1 is shown with the dotted line and the sound dampened by the structure of figure 2 is shown with the broken line It is obvious that there is obtained a substantial reduction of sound transmission by using the structural elements of the invention. A similar good effect is obtained for dampening of vibration and both sound and vibration in combination, whether the structural element is used in house building like in floors, walls or ceilings, or in machine boxes, in loud speakers, in motor cars, in boats, in airplanes etc.

It is to be understood that the structural element of the invention may be made both stiff and flexible. A flexible element, in which the plates are of metal plate or of plastics, and the complete element can be mounted on convex or concave surfaces, is well suited for use on curved surfaces like in motor cars, air planes, in boats and ships, in railway wagons, refrigerators, i freezing boxes, many types of machine structures etc. The element is also well suited as a support base for machines, machine tools etc. thereby reducing the vibrations which otherwise necessarily are transmitted through the floor, in particular floors of concrete, metal etc.

Tests have been made to determine the airborne sound insulation and the impact sound transmission of the products of the invention as illustrated in figures 10-13, a'd t,;e fesults thereof are shown in the diagrams of figures 14 and 15. The ,ests were made in a test house SUBSTITUTE SHEET

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i- 119- UUUI~ I WO 93/21402 PCT/SE92/00229 comprising a two storey detached house of brick/block construction. Ah tests 1, 2, 3 and 4 were made in the same pair of rooms with the floor of the upper room modified to produce the various test configurations. The calculated area of the separating floor was 14 m 2 As shown in figure the floor system comprised 29 x 44 mm timber joists set att 600 mm centres. The floor-covering was 18 mm floring grade chipboard, and the ceiling in the bottom room was 19 mm Gyproc plank and 12,5 mm Gyproc wallboard fixed to the underside of the joists.

First the airborne sound insulation and the impact sound transmission were tested in Test 1, and the results thereof are plotted under point 1 of figures 14 and 15, in which diagrams the horizontal axis shows the freuency in Hz and the vertical axis shows the sound level difference in decibel whereby the figure 14 illustrates the sound damping and figure 14 shows the impact sound transmission through the floor/ceiling. In Test 2 the floor was covered with a floor element of the type described in connection to figure 2 and consisting from top to bottom of 6 mm fibreboard bonded to 18 mm chipboard by beads of viscoelastic dampening material as described above spaced by 100 mm.

It is obvious that the floor of Test 2, shown in figure 11, had a surprisingly good airborne sound damping effect and a similarly surprisingly good reduction of impact sound transmission as compared with the original floor shown in figure In Test 3 the chipboard layer of figure 11 was substituted by 18 mm cement particle board as i!lustrated in figure 12. In this case a sound slab of 100 mineral wool was laid between the joists. It is obvious that the sound damping and impact reduction was much better than for the original floor, and even better than that of Test 2.

To investigate the influence of the thickness of the support plates of the sound and vibration damping element Test 4 was carried out, whereby the floor element consisted of 6 mm fibreboard bonded to 3,2 mm fibreboard by strings of the claimed viscoelastic material. In this case the polyester felt had a thickness of only 6 mm.

As shown the sound and vibration damping effect was very similar to those of Test 2, and it therefore could be concluded that there is no need for having such thick floor element as in figure i 1 except possibly for strength technical reasons and that it is often quite sufficient to have only S6 3,2 mm thick support elements.

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Ia WO 93/21402 PCT/SE92/00229 9 The diagrams of figures 14 and 15 very clearly show the good effect of the element according to the inventin.

Reference numerale 1 support plate 2 support plate 3 string of viscoelastic material 4 felt structural element 6 structural element 7 groove and tenon means 8 groove and tenon means 9 nozzle string of viscoelastic material 11 bottom plate 12 string of glue 13 glue nozzle 14 upper plate pressure application 16 felt 17 glue 18 pressure application i SUBSTITUTE SHEET iISA/SE

Claims

1. An integral structural or non-structural element having improved sound and vibration dampening capacity and being composed of two support plates 2) having therebetween spaced layers of a sco- elastic material, formed as strings or dots etc. of elastomeric material which are spaced from each other leaving an air space between the two support plates 2) in the areas between adjacent strings (10) of elastomeric material characterized in that the structural element carries, at the surface thereof to be mounted on the supporting base, a felt mat of a natural or synthetic felt fibre material.

2. A structural element according to claim 1, characterized in that the felt mat has a product weight of 300-1200 g/m 2 and having a thickness of 3-10 mm or preferably 5-9 mm.

3. A structural element according to claim 1 or 2, characterized in that the felt mat for house building structural elements is a polyester felt of needle/thermally bonded fibres or a mat or viscose, polypropylene, polyurethane or polyamid, eventually bonded by a glass fibre material as a reinforcing element thereof.

4. A structural element according to any of the preceding claims, cha'acterized in that the bottom support plate is of less thickness than the upper support plate whereby the bottom support plate for ordinary house building purposes preferably has a thickness of 3-8 mm and the upper support plate has a thickness of 8-22 mm.

A structural element according to any of the preceding claims, characterized in that the viscoelastic material is a synthetic elastomeric material applied in liquid form and chosen among the materials including styrene rubber, nitrilic iubber, silicon rubber, chloroprenic rubber and acrylic rubber, all having good adhesive properties, and all having a temperature resistance or maximum service temperature of 10 0 0C or more to be able to stand the temperature rise occuring due to the internal friction of the material while subjected to vibrations,

6. A structural element according to claim 5, characterized in that each string (10) of dampening material has a material thickness of between 1 and 5 mm, or preferably 1.5 to 2.5 mm and a width of 10-50 mm, and in i SUBSTITUTE SHEET i ,0 2 2 9 PCT l.iLcluonri Application 1 7 -05- 1993 S11 that adjacent strings (10) of dampening material are spaced from each other by a distance which is 50-500 mm.

7. A structural element according to claim 6, characterized in that strings (10) of dampening material are spaced 50-200 mm for carrying relatively heavy loads and 200-500 mm for carrying relatively light-weight loads.

8. A method of manufacturing a structural element according to any of the preceding claims having improved sound and/or vibration dampening capacity and being composed of two support plates 2) having therebetween spaced layers of a viscoelastic material, characterized in applying several spaced strings (10) of a viscoelastic synthetic damping material in liquid form, having a good adhesive activity in a in a thickness of 1-5 mm, a width of 50-500 mm and spaced from each other by a distance of 50-500 mm on the upper surface of a first support plate (11), allowing said liquid viscoelastic material (10) to completely set or polymerize, applying a another thin layer (12) of a viscoelastic synthetic glue in liquid form on top of the strings (10) of polymerized viscoelastic material, pressing a second support plate (14) onto the strings of viscoelastic material (10) with the glue surface layer (12), allowing the glue layer to polymerize thereby forming an integral three-part structural element 6), and finally applying a mat of natural or synthetic felt material (16) of a predetermined product weight, preferably of 300-1200 g/m 2 and a predetermined thickness, preferably a thickness of 3-10 mm, over the surface of the structural element 6) adapted to face the surface onto which the element is to be fastened. trimming and cutting the structural element,

9. Method according to claim 9, characterized in applying the strings of elastomeric material by moving the first support plate (11) at a predetermined speed past several nozzles laying oui the strings of the polymeric material.

Method according to claim 9, characterized in moulding strings of polymeric material separately, preferably on an adhesive- repellent material, allowing said strings to set or polymerize completely, covering one surface 'K SUBSTITUTE SHEET b r 12 of each string (10) with a thin layer of glue, preferably of the same material as that of the strings and applying said strings (10) on the top surface of the bottom support plate with the glue covered surface of the strings (10) facing said bottom support plate and proceeding the method as in claim 8.

11. An integral structural or non-structural element substantially as herein described with reference to and as illustrated in the accompanying drawings.

12. A method of manufacture of an integral structural or non-structural element substantially as herein descrbed with reference to and as illustrated in the accompanying drawings. Dated this 29th day of February 1996. II,' I I. 44 4 I 4 II II 44 ECOMAX ACOUSTICS LTD By its Patent Attorneys: GRIFFITH HACK CO. Fellows Institute of Patent Attorneys of Australia. RA4- T' 1